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. 2011 Sep;193(18):5045–5046. doi: 10.1128/JB.05531-11

Draft Genome Sequence of Gordonia neofelifaecis NRRL B-59395, a Cholesterol-Degrading Actinomycete

Fanglan Ge 1, Wei Li 1,*, Guiying Chen 1, Yuchang Liu 1, Guangxiang Zhang 1, Bin Yong 1, Qiong Wang 1, Nan Wang 1, Zhumei Huang 1, Weitian Li 1, Jing Wang 1, Cheng Wu 1, Qian Xie 1, Gang Liu 1
PMCID: PMC3165644  PMID: 21742880

Abstract

We report a draft sequence of the genome of Gordonia neofelifaecis NRRL B-59395, a cholesterol-degrading actinomycete isolated from fresh feces of a clouded leopard (Neofelis nebulosa). As predicted, the reported genome contains several gene clusters for cholesterol degradation. This is the second available genome sequence of the family Gordoniaceae.

GENOME ANNOUNCEMENT

The genus Gordonia was originally proposed by Tsukamura (in 1971) and belongs to the mycolic acid group of the Actinomycetes (13, 15). In recent years, it has attracted much interest for its ability to degrade xenobiotics, environmental pollutants (1), and recalcitrant natural polymers, such as rubber (9), dibenzothiophene (7), explosive hexogen (14), butyl benzyl phthalates, and cholesterol (4, 10). Quite a number of Gordonia species are opportunistic pathogens (6). However, in the genome database, the only genome sequence available at this time is Gordonia bronchialis DSM 43247 (5). Recently, our laboratory isolated and characterized Gordonia neofelifaecis (NRRL B-59395T) (11), a novel species of Gordonia which shows a high degree of ability to degrade steroidal compounds, and a draft genome sequence of this species is presented here.

The genome sequence was determined using Illumina Genome Analyzer II at the Beijing Genomics Institute (BGI) (Shenzhen, China). Draft assemblies were based on 500-Mb reads. All of the reads provided about 117-fold coverage of the genome. The GAII paired-end reads were assembled into 168 contigs in 47 scaffolds with the SOAPdenovo program. Putative open reading frames encoding more than 30 amino acid residues were predicted using Glimmer 3.0 (3). rRNA genes were identified by RNAmmer (8) and the tRNAscan-SE server (12). The scaffolds were searched against the KEGG and COG (Clusters of Orthologous Groups) databases to annotate the gene descriptions.

The draft genome of G. neofelifaecis NRRL B 59395 consists of 4,257,286 bases with a G+C content of 68.62%, and there are 4,032 putative coding sequences with an average length of 951 bp. The coding percentage is 90.3%. There are 46 genes for tRNAs and 5 rRNA loci.

A plethora of genes related to the catabolism of cholesterol were discovered. There are two genes encoding putative 3-ketosteroid-delta-1-dehydrogenase (KSTD), with 60 to 76% identity to orthologs in R. erythropolis SQ1; they catalyze the transhydrogenation of 3-keto-4-ene-steroid to 3-keto-1,4-diene-steroid. Three open reading frames encoding 3-ketosteroid 9-alpha-hydroxylase (KshA and KshB) were found. A gene cluster, SCNU_09391 to SCNU_09186, including about 30 genes, was discovered; most of the products of these genes share greatest identity to the ro04482-ro04705 cluster in Rhodococcus jostii RHA1 and the rv3492c-rv3574 cluster in Mycobacterium tuberculosis H37Rv (16), which encode all of the enzymes necessary to perform one full cycle of β-oxidation and are involved in shortening the cholesterol side chains. Similar to the igr locus Rv3545c to Rv3540c in M. tuberculosis (2, 16), the second cluster, SCNU_16768 to SCNU_16798, consists of a single operon containing genes for three acyl coenzyme A (acyl-CoA) dehydrogenases, a lipid-transfer protein, and a putative TetR-family transcriptional regulatory protein. A third cluster, SCNU_09181 to SCNU_09146, includes eight genes that are predicted to encode a multicomponent cholesterol uptake system: mce4ABCDEF and supAB (called the mce cluster) (16). The genome sequence of G. neofelifaecis and its annotation will provide further insight into the physiology and metabolic potential of Gordonia.

Nucleotide sequence accession numbers.

This Whole Genome Shotgun project has been deposited at DDBJ/EMBL/ GenBank under the accession number AEUD00000000. The version described in this paper is the first version, AEUD01000000.

Acknowledgments

This work was supported by the Sichuan Provincial Science & Technology Department (2008JY0103-1, 2009JY0067).

We thank Dongxia Li for her careful reading of the manuscript.

Footnotes

Published ahead of print on 8 July 2011.

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